Geometrically nonlinear analysis of the stability of the stiffened plate taking into account the interaction of eigenforms of buckling

Abstract

The aims of this work are a detailed consideration in a geometrically nonlinear formulation of the stages of the equilibrium behavior of a compressed stiffened plate, taking into account the interaction of the general form of buckling and local forms of wave formation in the plate or in the reinforcing ribs, comparison of the results of the semi-analytical solution of the system of nonlinear equations with the results of the numerical solution on the Patran-Nastran FEM complex of the problem of subcritical and postcritical equilibrium of a compressed stiffened plate. Methods. Geometrically-nonlinear analysis of displacement fields, deformations and stresses, calculation of eigenforms of buckling and construction of bifurcation solutions and solutions for equilibrium curves with limit points depending on the initial imperfections. An original method is proposed for determining critical states and obtaining bilateral estimates of critical loads at limiting points. Results. An algorithm for studying the equilibrium states of a stiffened plate near critical points is described in detail and illustrated by examples, using the first nonlinear (cubic terms) terms of the potential energy expansion, the coordinates of bifurcation points and limit points, as well as the corresponding values of critical loads. The curves of the critical load sensitivity are plotted depending on the value of the initial imperfections of the total deflection. Equilibrium curves with characteristic bifurcation points of local wave formation are constructed using a numerical solution. For the case of action of two initial imperfections, an algorithm is proposed for obtaining two-sided estimates of critical loads at limiting points.

About the authors

Gaik A. Manuylov

Russian University of Transport

Author for correspondence.
Email: grudtsyna_ira90@mail.ru

Associate Professor of the Department of Structural Mechanics

15 Obraztsova St, Moscow, 127994, Russian Federation

Sergey B. Kositsyn

Russian University of Transport

Email: grudtsyna_ira90@mail.ru

Head of the Department of Theoretical Mechanics, adviser of the RAACS, D.Sc. in Engineering, Professor

15 Obraztsova St, Moscow, 127994, Russian Federation

Irina E. Grudtsyna

Russian University of Transport

Email: grudtsyna_ira90@mail.ru

postgraduate student of the Department of Theoretical Mechanics

15 Obraztsova St, Moscow, 127994, Russian Federation

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Copyright (c) 2021 Manuylov G.A., Kositsyn S.B., Grudtsyna I.E.

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